RNA recombination plays a major role in genomic change during circulation of coxsackie B viruses

RNA recombination has been shown to occur during circulation of enteroviruses, but most studies have focused on poliovirus. To examine the role of recombination in the evolution of the coxsackie B viruses (CVB), we determined the partial sequences of four genomic intervals for multiple clinical isolates of each of the six CVB serotypes isolated from 1970 to 1996. The regions sequenced were the 5'-nontranslated region (5'-NTR) (350 nucleotides [nt]), capsid (VP4-VP2, 416 nt, and VP1, approximately 320 nt), and polymerase (3D, 491 nt). Phylogenetic trees were constructed for each genome region, using the clinical isolate sequences and those of the prototype strains of all 65 enterovirus serotypes. The partial VP1 sequences of each CVB serotype were monophyletic with respect to serotype, as were the VP4-VP2 sequences, in agreement with previously published studies. In some cases, however, incongruent tree topologies suggested that intraserotypic recombination had occurred between the sequenced portions of VP2 and VP1. Outside the capsid region, however, isolates of the same serotype were not monophyletic, indicating that recombination had occurred between the 5'-NTR and capsid, the capsid and 3D, or both. Almost all clinical isolates were recombinant relative to the prototype strain of the same serotype. All of the recombination partners appear to be members of human enterovirus species B. These results suggest that recombination is a frequent event during enterovirus evolution but that there are genetic restrictions that may influence recombinational compatibility.     

Recombination in the Evolution of Enterovirus C Species Sub-Group that Contains Types CVA-21, CVA-24, EV-C95, EV-C96 and EV-C99

Genetic recombination is considered to be a very frequent phenomenon among enteroviruses (Family Picornaviridae, Genus Enterovirus). However, the recombination patterns may differ between enterovirus species and between types within species. Enterovirus C (EV-C) species contains 21 types. In the capsid coding P1 region, the types of EV-C species cluster further into three sub-groups (designated here as A–C). In this study, the recombination pattern of EV-C species sub-group B that contains types CVA-21, CVA-24, EV-C95, EV-C96 and EV-C99 was determined using partial 5′UTR and VP1 sequences of enterovirus strains isolated during poliovirus surveillance and previously published complete genome sequences. Several inter-typic recombination events were detected. Furthermore, the analyses suggested that inter-typic recombination events have occurred mainly within the distinct sub-groups of EV-C species. Only sporadic recombination events between EV-C species sub-group B and other EV-C sub-groups were detected. In addition, strict recombination barriers were inferred for CVA-21 genotype C and CVA-24 variant strains. These results suggest that the frequency of inter-typic recombinations, even within species, may depend on the phylogenetic position of the given viruses.     

Evidence for frequent recombination within species human enterovirus B based on complete genomic sequences of all thirty-seven serotypes

The species Human enterovirus B (HEV-B) in the family Picornaviridae consists of coxsackievirus A9; coxsackieviruses B1 to B6; echoviruses 1 to 7, 9, 11 to 21, 24 to 27, and 29 to 33; and enteroviruses 69 and 73. We have determined complete genome sequences for the remaining 22 HEV-B serotypes whose sequences were not represented in public databases and analyzed these in conjunction with previously available complete sequences in GenBank. Members of HEV-B were monophyletic relative to all other human enterovirus species in all regions of the genome except in the 5'-nontranslated region (NTR), where they are known to cluster with members of HEV-A. Within HEV-B, phylogenies constructed from the structural (P1) and nonstructural regions of the genome (P2 and P3) are incongruent, suggesting that recombination had occurred. Similarity plots and bootscanning analysis across the complete genome identified multiple sites at which the phylogeny of a given strain's sequence shifted, indicating potential recombination points. These points are distributed in the 5'-NTR and throughout P2 and P3, but no sites with >80% bootstrap support were identified within the capsid. Individual sequence comparisons and phylogenetic analyses suggest that members of HEV-B have recombined with one another on multiple occasions, resulting in a complex mosaic of sequences derived from multiple parental viruses in the nonstructural regions of the genome. We conclude that RNA recombination is a common mechanism for enterovirus evolution and that recombination within the nonstructural regions of the genome (P2 and P3) has been observed only among members of the same species.     

Human endogenous retroviral elements as indicators of ectopic recombination events in the primate genome

HERV elements make up a significant fraction of the human genome and, as interspersed repetitive elements, have the capacity to provide substrates for ectopic recombination and gene conversion events. To understand the extent to which these events occur and gain further insight into the complex evolutionary history of these elements in our genome, we undertook a phylogenetic study of the long terminal repeat sequences of 15 HERV-K(HML-2) elements in various primate species. This family of human endogenous retroviruses first entered the primate genome between 35 and 45 million years ago. Throughout primate evolution, these elements have undergone bursts of amplification. From this analysis, which is the largest-scale study of HERV sequence dynamics during primate evolution to date, we were able to detect intraelement gene conversion and recombination at five HERV-K loci. We also found evidence for replacement of an ancient element by another HERV-K provirus, apparently reflecting an occurrence of retroviral integration by homologous recombination. The high frequency of these events casts doubt on the accuracy of integration time estimates based only on divergence between retroelement LTRs.     

Recombination and population mosaic of a multifunctional viral gene, adeno-associated virus cap

Homologous recombination is a dominant force in evolution and results in genetic mosaics. To detect evidence of recombination events and assess the biological significance of genetic mosaics, genome sequences for various viral populations of reasonably large size are now available in the GenBank. We studied a multi-functional viral gene, the adeno-associated virus (AAV) cap gene, which codes for three capsid proteins, VP1, VP2 and VP3. VP1-3 share a common C-terminal domain corresponding to VP3, which forms the viral core structure, while the VP1 unique N-terminal part contains an enzymatic domain with phospholipase A2 activity. Our recombinant detection program (RecI) revealed five novel recombination events, four of which have their cross-over points in the N-terminal, VP1 and VP2 unique region. Comparison of phylogenetic trees for different cap gene regions confirmed discordant phylogenies for the recombinant sequences. Furthermore, differences in the phylogenetic tree structures for the VP1 unique (VP1u) region and the rest of cap highlighted the mosaic nature of cap gene in the AAV population: two dominant forms of VP1u sequences were identified and these forms are linked to diverse sequences in the rest of cap gene. This observation together with the finding of frequent recombination in the VP1 and 2 unique regions suggests that this region is a recombination hot spot. Recombination events in this region preserve protein blocks of distinctive functions and contribute to convergence in VP1u and divergence of the rest of cap. Additionally the possible biological significance of two dominant VP1u forms is inferred.     

2008～2010年河南省人肠道病毒71型基因特征和重组分析

对河南省2008～2010年河南省人肠道病毒71型进行基因特征及重组特点研究。对河南省2008～2010年分离的5株肠道病毒EV71型构建VP1序列系统进化树并分析其全基因组序列的重组特点。VP1序列系统进化分析显示2008～2010年河南株均属于C4基因型的C4a亚群,Bootscan分析和5’NCR、P1、P2、P3区的进化树证实C4基因型在2A～2B处存在EV71的B基因型和C基因型的型内重组及在3B～3C处存在EV71的B基因型和CA16/G-10间的型间重组。2008～2010年河南EV71分离株为C4基因型的C4a亚群,与2004年以来的中国大陆优势株流行趋势完全一致,EV71C4基因型存在基因型内和型间双重组现象。     

Recombination in circulating enteroviruses

Recombination is a well-known phenomenon for enteroviruses. However, the actual extent of recombination in circulating nonpoliovirus enteroviruses is not known. We have analyzed the phylogenetic relationships in four genome regions, VP1, 2A, 3D, and the 5' nontranslated region (NTR), of 40 enterovirus B strains (coxsackie B viruses and echoviruses) representing 11 serotypes and isolated in 1981 to 2002 in the former Soviet Union states. In the VP1 region, strains of the same serotype expectedly grouped with their prototype strain. However, as early as the 2A region, phylogenetic grouping differed significantly from that in the VP1 region and indicated recombination within the 2A region. Moreover, in the 5' NTR and 3D region, only 1 strain of 40 grouped with its prototype strain. Instead, we observed a major group in both the 5' NTR and the 3D region that united most (in the 5' NTR) or all (in the 3D region) of the strains studied, regardless of the serotype. Subdivision within that major group in the 3D region correlated with the time of virus isolation but not with the serotype. Therefore, we conclude that a majority, if not all, circulating enterovirus B strains are recombinants relative to the prototype strains, isolated mostly in the 1950s. Moreover, the ubiquitous recombination has allowed different regions of the enterovirus genome to evolve independently. Thus, a novel model of enterovirus genetics is proposed: the enterovirus genome is a stable symbiosis of genes, and enterovirus species consist of a finite set of capsid genes responsible for different serotypes and a continuum of nonstructural protein genes that seem to evolve in a relatively independent manner.     

Genetic relationship between cocirculating Human enteroviruses species C

Recombination events between human enteroviruses (HEV) are known to occur frequently and to participate in the evolution of these viruses. In a previous study, we reported the isolation of a panel of viruses belonging to the Human enterovirus species C (HEV-C) that had been cocirculating in a small geographic area of Madagascar in 2002. This panel included type 2 vaccine-derived polioviruses (PV) that had caused several cases of acute flaccid paralysis in humans. Previous partial sequencing of the genome of these HEV-C isolates revealed considerable genetic diversity, mostly due to recombination. In the work presented herein, we carried out a more detailed characterization of the genomes of viruses from this collection. First, we determined the full VP1 sequence of 41 of these isolates of different types. These sequences were compared with those of HEV-C isolates obtained from other countries or in other contexts. The sequences of the Madagascan isolates of a given type formed specific clusters clearly differentiated from those formed by other strains of the same type isolated elsewhere. Second, we sequenced the entire genome of 10 viruses representing most of the lineages present in this panel. All but one of the genomes appeared to be mosaic assemblies of different genomic fragments generated by intra- and intertypic recombination. The location of the breakpoints suggested potential preferred genomic regions for recombination. Our results also suggest that recombination between type HEV-99 and other HEV-C may be quite rare. This first exhaustive genomic analysis of a panel of non-PV HEV-C cocirculating in a small human population highlights the high frequency of inter and intra-typic genetic recombination, constituting a widespread mechanism of genetic plasticity and continually shifting the HEV-C biodiversity.     

Detection and genetic characterization of enteroviruses circulating among wild populations of chimpanzees in Cameroon: relationship with human and simian enteroviruses

Enteroviruses (EVs), members of the family Picornaviridae, are a genetically and antigenically diverse range of viruses causing acute infections in humans and several Old World monkey (OWM) species. Despite their known wide distribution in primates, nothing is currently known about the occurrence, frequency, and genetic diversity of enteroviruses infecting apes. To investigate this, 27 chimpanzee and 27 gorilla fecal samples collected from undisturbed jungle areas with minimal human contact in Cameroon were screened for EVs. Four chimpanzee samples were positive, but none of the gorilla samples were positive. Genetic characterization of the VP1, VP4, and partial VP2 genes, the 5' untranslated region, and partial 3Dpol sequences enabled chimpanzee-derived EVs to be identified as (i) the species A type, EV76, (ii) a new species D type assigned as EV111, along with a human isolate from the Democratic Republic of Congo previously described by the International Committee on the Taxonomy of Viruses, and (iii) a new species B type (assigned as EV110) most closely related to, although a distinct type from, the SA5 isolate recovered from a vervet monkey. The identification of EVs infecting chimpanzees related to those circulating in human and OWM populations provides evidence for cross-species transmission of EVs between primates. However, the direction of transfer and the existence of primate sources of zoonotic enterovirus infections in humans require further investigation of population exposure and more extensive characterization of EVs circulating in wild ape populations.     

Circulation of enteroviruses in Cyprus assessed by molecular analysis of clinical specimens and sewage isolates

Aims: To study the circulation of non‐polio enteroviruses in the Cypriot population and assess the clinical relevance of different serotypes by the analysis of clinical specimens and environmental samples. Methods and Results: Sewage samples were collected on a monthly basis for 2 years from all five districts of Cyprus. Enteroviruses were isolated using the VIRADEN method and typed by partial VP1 region sequencing. In addition, all enterovirus‐positive clinical samples received during this 2‐year period were typed, and a phylogenetic comparison of clinical and sewage samples based on the partial VP1 sequences was made. A significant difference between the most common serotypes found in sewage and clinical samples was observed. While Coxsackieviruses B constituted the most frequent serotypes in sewages, Echoviruses 30 and 18 prevailed in clinical samples. Conclusions: The phylogenetic analysis revealed that certain enterovirus strains circulate in the population over long period of time, while others are observed only sporadically and disappear quickly. For some serotypes, it was observed that several strains were cocirculating in the population but only some of them being detected also in clinical specimens. Significance and Impact of the Study: This study, for the first time, compares enteroviruses isolated from environmental samples and clinical specimens on a molecular level, which allowed for strain identification and discrimination. A more comprehensive molecular analysis of these strains will help identify factors, which determine different degrees of pathogenicity.     

Complete genome sequence of a recombinant coxsackievirus b4 from a patient with a fatal case of hand, foot, and mouth disease in guangxi, china

The coxsackievirus B4 (CVB4) belongs to human enterovirus B species within the family Picornaviridae. Here we report a novel complete genome sequence of a recombinant CVB4 strain, CVB4/GX/10, which was isolated from a patient with a fatal case of hand, foot, and mouth disease in China. The complete genome consists of 7,293 nucleotides, excluding the 3' poly(A) tail, and has an open reading frame that maps between nucleotide positions 742 and 7293 and encodes a 2,183-amino-acid polyprotein. Phylogenetic analysis based on different genome regions reveals that CVB4/GX/10 is closest to a CVB4 strain, EPIHFMD-CLOSE CONTACT-16, in the 5' half (VP4～2B) of the genome, although it is closer to a Chinese CVB5 strain, CVB5/Henan/2010, in the 3' half (2C～3D) of the genome. Furthermore, similar bootscan analysis based on the whole genomes demonstrates that recombination has possibly occurred within the 2C domain and that CVB4/GX/10 is a possible progeny of intertypic recombination of the CVB4 strain EPIHFMD-CLOSE CONTACT-16 and CVB5/Henan/2010 that occurred during their cocirculation and evolution, which is a relatively common phenomenon in enteroviruses.     

Genome Characterisation of Enteroviruses 117 and 118: A New Group within Human Enterovirus Species C

The more than 120 genotypes of human enteroviruses (HEVs) reflect a wide range of evolutionary divergence, and there are 23 currently classified as human enterovirus C species (HEV-C). Two new HEV-C (EV-C117 and EV-C118) were identified in the Community-Acquired Pneumonia Pediatric Research Initiative (CAP-PRI) study, and the present paper describes the characterisation of the complete genome of one EV-C117 strain (LIT22) and two EV-C118 (ISR38 and ISR10) strains. The EV-C117 and EV-C118 5′UTR sequences were related to those of EV-C104, EV-C105 and EV-C109, and were slightly shorter than those of other HEV A-D species. Similarity plot analyses showed that EV-C117 and EV-C118 have a P1 region that is highly divergent from that of the other HEV-C, and phylogenetic analyses highly supported a monophyletic group consisting of EV-C117, EV-C118, EV-C104, EV-C105 and EV-C109 strains. Phylogenetic, Simplot and Bootscan analyses indicated that recombination was not the main mechanism of EV-C117 and EV-C118 evolution, thus strengthening the hypothesis of the monophyletic origin of the coding regions, as in the case of other HEV-C. Phylogenetic analysis also revealed the emergence of a new group within HEV-C that is divided into two subgroups. Nucleotide and amino acid identity in VP1 sequences have been established as useful criteria for assigning new HEV types, but analysis of the complete P1 region improves resolution.     

Recombination in the genesis and evolution of hepatitis B virus genotypes

Hepatitis B virus (HBV) infection is widely distributed in both human and ape populations throughout the world and is a major cause of human morbidity and mortality. HBV variants are currently classified into the human genotypes A to H and species-associated chimpanzee and gibbon/orangutan groups. To examine the role of recombination in the evolution of HBV, large-scale data retrieval and automated phylogenetic analysis (TreeOrder scanning) were carried out on all available published complete genome sequences of HBV. We detected a total of 24 phylogenetically independent potential recombinants (different genotype combinations or distinct breakpoints), eight of which were previously undescribed. Instances of intergenotype recombination were observed in all human and ape HBV variants, including evidence for a novel gibbon/genotype C recombinant among HBV variants from Vietnam. By recording sequence positions in trees generated from sequential fragments across the genome, violations of phylogeny between trees also provided evidence for frequent intragenotype recombination between members of genotypes A, D, F/H, and gibbon variants but not in B, C, or the Asian B/C recombinant group. In many cases, favored positions for both inter- and intragenotype recombination matched positions of phylogenetic reorganization between the human and ape genotypes, such as the end of the surface gene and the core gene, where sequence relationships between genotypes changed in the TreeOrder scan. These findings provide evidence for the occurrence of past, extensive recombination events in the evolutionary history of the currently classified genotypes of HBV and potentially in changes in its global epidemiology and associations with human disease.     

Human Enterovirus 109: a Novel Interspecies Recombinant Enterovirus Isolated from a Case of Acute Pediatric Respiratory Illness in Nicaragua

Enteroviruses (Picornaviridae family) are a common cause of human illness worldwide and are associated with diverse clinical syndromes, including asymptomatic infection, respiratory illness, gastroenteritis, and meningitis. In this study, we report the identification and complete genome sequence of a novel enterovirus isolated from a case of acute respiratory illness in a Nicaraguan child. Unbiased deep sequencing of nucleic acids from a nose and throat swab sample enabled rapid recovery of the full-genome sequence. Phylogenetic analysis revealed that human enterovirus 109 (EV109) is most closely related to serotypes of human enterovirus species C (HEV-C) in all genomic regions except the 5′ untranslated region (5′ UTR). Bootstrap analysis indicates that the 5′ UTR of EV109 is likely the product of an interspecies recombination event between ancestral members of the HEV-A and HEV-C groups. Overall, the EV109 coding region shares 67 to 72% nucleotide sequence identity with its nearest relatives. EV109 isolates were detected in 5/310 (1.6%) of nose and throat swab samples collected from children in a pediatric cohort study of influenza-like illness in Managua, Nicaragua, between June 2007 and June 2008. Further experimentation is required to more fully characterize the pathogenic role, disease associations, and global distribution of EV109.The genus Enterovirus (EV) in the family Picornaviridae is a group of related viruses that are associated with a spectrum of disease, ranging from subclinical infections to acute respiratory and gastrointestinal illness to more severe manifestations, such as aseptic meningitis, encephalitis, and acute flaccid paralysis (16, 32). Enteroviruses are small, nonenveloped viruses that share a genomic organization. The RNA genome is a ∼7.5 kb single-stranded, positive-sense, polyadenylated molecule, with a single, long open reading frame flanked by 5′ and 3′ untranslated regions (UTRs). The 5′ UTR is ∼700 nucleotides in length and contains highly structured secondary elements with internal ribosomal entry site (IRES) function. The ∼2,200-amino-acid (aa) polyprotein is cotranslationally processed by viral proteases to yield structural (VP4, VP2, VP3, and VP1) and nonstructural (2A, 2B, 2C, 3A, 3B, 3C, and 3D) proteins (32). Current enterovirus classification is based on the high sequence divergence within the VP1 capsid region, which has been shown to correspond with serotype neutralization (27, 28). Human enterovirus (HEV) types are currently classified into four species, human enterovirus A (HEV-A), HEV-B, HEV-C (including poliovirus), and HEV-D, based on the four phylogenetic clusters observed in comparisons of the coding region sequences. An enterovirus is considered a new type within a species if it possesses <75% nucleotide identity and <85% amino acid identity with known members across the VP1 sequence (27, 30). Molecular identification methods play a crucial role in rapid, sensitive enterovirus diagnostics and have led to the recent discovery of several novel enteroviruses (29, 31, 40, 42, 44). Most approaches target a limited number of conserved regions in the 5′ UTR and VP4-VP2 junction or seek to ascertain serotype information by probing antigenic regions, such as VP1 (5).Picornavirus RNA-dependent RNA polymerases are highly error prone and lack proofreading ability, resulting in a misincorporation frequency of 1 per 10³ to 10⁴ nucleotides (48). The relative infidelity of these polymerases is believed to enable rapid adaptability under selective pressure. Large-impact evolutionary events, such as recombination within and between enterovirus serotypes, also contribute to their evolution and genetic diversity (3, 8, 26, 39) and may lead to changes in disease associations with human enterovirus infections. Human enteroviruses are classified into four species based on coding region sequence phylogeny, and intraspecies recombination events between enteroviruses that are closely related in the coding region are well documented (26, 38, 39). All known enterovirus 5′ UTR sequences, however, cluster into two groups containing either HEV-A and -B sequences or HEV-C and -D sequences. Recent findings have described enterovirus genomes with a coding region that clusters with one species and a 5′ UTR that clusters with a different species, suggesting possible interspecies recombination events (41, 44). Understanding the recombination-driven evolution of HEV-C viruses is of particular public health concern due to the viruses'' ability to recombine with vaccine poliovirus, resulting in circulating, highly neurovirulent vaccine-derived polioviruses (17, 21, 34). It is unclear whether recombination events between poliovirus and HEV-C viruses allow for the rapid acquisition of traits that increase pathogenic and circulation potential.The enterovirus pathogenicity spectrum is related to tissue tropism and is largely determined by cellular receptor usage. Most picornaviruses use receptors from the immunoglobulin superfamily of proteins, such as intracellular adhesion molecule-1 (ICAM-1) or coxsackievirus-adenovirus receptor (CAR) (36). A distinct subgroup of HEV-C viruses, which includes coxsackievirus (CAV) A1, A19, and A22 and enterovirus 104, has not yet been grown successfully in cell culture, and the receptor molecule for this subgroup is unknown (6). HEV-C viruses are believed to be the ancestral source of poliovirus, which resulted from a capsid mutation that caused a cellular receptor switch from ICAM-1 to CD155 (poliovirus receptor [PVR]) (17).In this study, we report the discovery and characterization of a novel human enterovirus type within species HEV-C, for which we propose the designation human enterovirus 109 (EV109). Sequence analysis reveals considerable nucleotide divergence in the 5′ UTR between EV109 and other HEV-C types, and scanning bootstrap analysis supports the hypothesis that EV109 is the product of an interspecies recombination event with an ancestral member of the HEV-A group. Viral capsid amino acid alignments and homology modeling reveal the predicted three-dimensional arrangement of divergent and conserved residues of EV109 compared with other related enteroviruses. We also report highly similar EV109 isolates within multiple cases of acute pediatric respiratory illness in Managua, Nicaragua.     

2009年云南省2株肠道病毒71型分离株全基因组序列遗传特性分析

对2009年云南省肠道病毒71型分离株KMM09和KM186-09进行全基因组序列测序,并与我国及其它国家流行的EV71基因型进行比较和进化分析。KMM09和KM186-09基因组长为7 409bp,编码2 193个氨基酸,VP1系统进化分析显示2009年云南分离株属于C4基因型的C4a亚型。在结构区,与其它基因型相比较,C基因型之间的核苷酸和氨基酸的同源性高于其它基因型;而在非结构区,C4与B基因型和CA16原型株G10同源性高于其它C基因亚型。通过RDP3重组软件和blast比对分析,发现EV71C4基因型与B3基因型,与CA16原型株G10的基因组在非结构区存在重组。EV71全基因组序列的比较和分析,对了解引起我国手足口病暴发或流行C4基因亚型EV71毒株的遗传特性具有重要意义。     

人博卡病毒基因克隆及衣壳编码基因序列变异分析

为了解人博卡病毒(Human Bocavirus,HBoV)VP1基因进化关系;阐明HBoV目前具体的变化规律,用PCR的方法扩增了1株HBoV的全基因和9株HBoV的VP1基因,克隆并测序,在此基础上,将HBoV的全基因序列和衣壳序列分别与细小病毒亚科其他14个有代表性的病毒进行遗传分析,构建进化树,对目前所有可得到的HBoV的17个衣壳蛋白进行二级结构分析和抗原性分析。结果显示:HBoV全基因序列与B19关系较远,但衣壳序列遗传关系较近。以有典型性的猫瘟细小病毒(Feline parvovirus,FPV)衣壳蛋白为参照,分析多个HBoV衣壳序列之间的变异情况,显示HBoV衣壳的二级结构基础表现出较高的保守性,序列之间的变化主要发生在高抗原区域和感染活性区域。衣壳病毒变异情况显示HBoV在稳定自身的情况下表现出一定的活跃性以逃避免疫反应,也表现出一定的感染适应力。     

Production of cross-reactive peptide antibodies against viral capsid proteins of human enterovirus B to apply diagnostic reagent

The coxsackievirus group B (CVB) of the genus Enterovirus and the species human enterovirus B is a nonenveloped virus containing a single-stranded positive-sense RNA genome. Coxsackievirus has icosahedral symmetry and four capsid proteins, VP1, VP2, VP3, and VP4. Specific antibodies against each viral protein are prerequisites for various studies. In this study, we developed seven peptide-derived antibodies directed against coxsackievirus VP1 (NO1-NO5), VP2 (B3), and VP3 (GL3). We developed a type-specific antibody (NO1) and broadly cross-reactive antibodies (NO3 and NO5) to VP1. Anti-VP2 and anti-VP3 antibodies (B3 and GL3, respectively) are also cross-reactive to human enterovirus B such as CVB and echoviruses. Their sensitivities and reactivities are likely to be better than those of the commercial VP1 monoclonal antibody (MAb). The dot-blot analysis also showed that NO5 against VP1 is able to detect less than 1 microg [2x10(6) plaque-forming unit (pfu) of CVB3] of viruses, suggesting that it could be used to develop a diagnostic kit that can directly detect human enterovirus B. The antibodies produced here may allow us to undertake several studies, such as those involving viral trafficking, expression kinetics, and the roles of viral proteins in infection, and the development of diagnostic kits.     

Molecular phylogeny and proposed classification of the simian picornaviruses.

The simian picornaviruses were isolated from various primate tissues during the development of general tissue culture methods in the 1950s to 1970s or from specimens derived from primates used in biomedical research. Twenty simian picornavirus serotypes are recognized, and all are presently classified within the Enterovirus genus. To determine the phylogenetic relationships among all of the simian picornaviruses and to evaluate their classification, we have determined complete VP1 sequences for 19 of the 20 serotypes. Phylogenetic analysis showed that A13, SV19, SV26, SV35, SV43, and SV46 are members of human enterovirus species A, a group that contains enterovirus 71 and 11 of the coxsackie A viruses. SA5 is a member of human enterovirus species B, which contains the echoviruses, coxsackie B viruses, coxsackievirus A9, and enterovirus 69. SV6, N125, and N203 are related to one another and, more distantly, to species A human enteroviruses, but could not be definitely assigned to a species. SV4 and SV28 are closely related to one another and to A-2 plaque virus, but distinct from other enteroviruses, suggesting that these simian viruses are members of a new enterovirus species. SV2, SV16, SV18, SV42, SV44, SV45, and SV49 are related to one another but distinct from viruses in all other picornavirus genera, suggesting that they may comprise a previously unknown genus in Picornaviridae. Several simian virus VP1 sequences (N125 and N203; SV4 and SV28; SV19, SV26, and SV35; SV18 and SV44; SV16, SV42, and SV45) are greater than 75% identical to one another (and/or greater than 85% amino acid identity), suggesting that the true number of distinct serotypes among the viruses surveyed is less than 20.     

Homologous recombination between different genotypes of hepatitis B virus

Phylogenetic analysis was used to examine the evolutionary relationships among 99 complete HBV sequences. Analysis revealed nine viral genomes clustered with different genotypes depending on genome region analyzed. This discordance indicated that recombination events occurred during HBV history. The putative breakpoints between genomes of different genotypes have been mapped. Six mosaic genomes representing B/C hybrids were isolated in East Asia and three A/D hybrids in Italy. At least some recombinant strains appear to be fully viable and possess high evolutionary potential. As a result, B/C recombinants overspread through the East Asia region. They were found among the isolates from Japan, China and Indonesia. Our results suggest that recombination is a significant and relatively frequent event in the evolution of HBV genome. A possible mechanism and the implications of recombination for the natural history of HBV, clinically important properties, and phylogenetic reconstruction are discussed.     

Epidemics and Frequent Recombination within Species in Outbreaks of Human Enterovirus B-Associated Hand,Foot and Mouth Disease in Shandong China in 2010 and 2011

The epidemiology and molecular characteristics of human enterovirus B (HEV-B) associated with hand, foot and mouth disease (HFMD) outbreaks in China are not well known. In the present study, we tested 201 HEV isolates from 233 clinical specimens from patients with severe HFMD during 2010–2011 in Linyi, Shandong, China. Of the 201 isolates, 189 were fully typed and 18 corresponded to HEV-B species (six serotypes CVA9, CVB1, CVB4, Echo 6, Echo 25 and Echo 30) using sensitive semi-nested polymerase chain reaction analysis of VP1 gene sequences. Phylogenetic analysis based on the VP1 region showed that eight E30SD belonged to a novel sub-genogroup D2; E25SD belonged to a novel sub-genogroup D6; E6SD belonged to sub-lineage C6 and five CVB1SD belonged to subgroup 4C; and B4SD belonged sub-lineage D2. The full viral genomes of the CVB1SD, E6SD, E25SD and E30SD isolates were sequenced. Analysis of phylogenetic and similarity plots indicated that E25SD recombined with E25-HN-2, E30FDJS03 and E4AUS250 at noncontiguous P2A–P3D regions, while E30SD, E30FDJ03, E25-HN-2 and E9 DM had shared sequences in discrete regions of P2 and P3. Both E6SD and B1SD shared sequences with E1-HN, B4/GX/10, B5-HN, and A9-Alberta in contiguous regions of most of P2 and P3. Genetic algorithm recombination detection analysis further confirmed the existence of multiple potential recombination points. In conclusion, analysis of the complete genomes of E25SD, E30SD, CVB1SD and E6SD isolated from HFMD patients revealed that they formed novel subgenogroup. Given the prevalence and recombination of these viruses in outbreaks of HFMD, persistent surveillance of HFMD-associated HEV-B pathogens is required to predict potential emerging viruses and related disease outbreaks.